/**********
Copyright 1990 Regents of the University of California.  All rights reserved.
Author: 1988 Thomas L. Quarles
Modified: 2000 AlansFixes
**********/

#include "ngspice/ngspice.h"
#include <stdio.h>
#include "ngspice/ifsim.h"
#include "ngspice/inpdefs.h"
#include "ngspice/inpmacs.h"
#include "ngspice/fteext.h"
#include "inpxx.h"
#include "ngspice/cpdefs.h"
#include "ngspice/tskdefs.h"

static int
dot_noise(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
          TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int which;			/* which analysis we are performing */
	int error;			/* error code temporary */
	char *name;			/* the resistor's name */
	char *nname1;		/* the first node's name */
	char *nname2;		/* the second node's name */
	CKTnode *node1;		/* the first node's node pointer */
	CKTnode *node2;		/* the second node's node pointer */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	char *steptype;		/* ac analysis, type of stepping function */

	int found;
	char *point;

	/* .noise V(OUTPUT,REF) SRC {DEC OCT LIN} NP FSTART FSTOP <PTSPRSUM> */
	which = ft_find_analysis("NOISE");
	if (which == -1) {
		LITERR("Noise analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Noise Analysis", &foo, task));
	INPgetTok(&line, &name, 1);

	/* Make sure the ".noise" command is followed by V(xxxx).  If it
	   is, extract 'xxxx'.  If not, report an error. */

	if (name != NULL) {

		if ((*name == 'V' || *name == 'v') && !name[1]) {

			INPgetNetTok(&line, &nname1, 0);
			INPtermInsert(ckt, &nname1, tab, &node1);
			ptemp.nValue = node1;
			GCA(INPapName, (ckt, which, foo, "output", &ptemp));

			if (*line != ')') {
				INPgetNetTok(&line, &nname2, 1);
				INPtermInsert(ckt, &nname2, tab, &node2);
				ptemp.nValue = node2;
			} else {
				ptemp.nValue = gnode;
			}
			GCA(INPapName, (ckt, which, foo, "outputref", &ptemp));

			INPgetTok(&line, &name, 1);
			INPinsert(&name, tab);
			ptemp.uValue = name;
			GCA(INPapName, (ckt, which, foo, "input", &ptemp));

			INPgetTok(&line, &steptype, 1);
			ptemp.iValue = 1;
			error = INPapName(ckt, which, foo, steptype, &ptemp);
			if (error)
				current->error = INPerrCat(current->error, INPerror(error));
			parm = INPgetValue(ckt, &line, IF_INTEGER, tab);
			error = INPapName(ckt, which, foo, "numsteps", parm);
			if (error)
				current->error = INPerrCat(current->error, INPerror(error));
			parm = INPgetValue(ckt, &line, IF_REAL, tab);
			error = INPapName(ckt, which, foo, "start", parm);
			if (error)
				current->error = INPerrCat(current->error, INPerror(error));
			parm = INPgetValue(ckt, &line, IF_REAL, tab);
			error = INPapName(ckt, which, foo, "stop", parm);
			if (error)
				current->error = INPerrCat(current->error, INPerror(error));

			/* now see if "ptspersum" has been specified by the user */

			for (found = 0, point = line; (!found) && (*point != '\0'); found = ((*point != ' ') && (*(point++) != '\t')))
				;
			if (found) {
				parm = INPgetValue(ckt, &line, IF_INTEGER, tab);
				error = INPapName(ckt, which, foo, "ptspersum", parm);
				if (error)
					current->error = INPerrCat(current->error, INPerror(error));
			} else {
				ptemp.iValue = 0;
				error = INPapName(ckt, which, foo, "ptspersum", &ptemp);
				if (error)
					current->error = INPerrCat(current->error, INPerror(error));
			}
		} else
			LITERR("bad syntax "
			       "[.noise v(OUT) SRC {DEC OCT LIN} "
			       "NP FSTART FSTOP <PTSPRSUM>]\n");
	} else {
		LITERR("bad syntax "
		       "[.noise v(OUT) SRC {DEC OCT LIN} "
		       "NP FSTART FSTOP <PTSPRSUM>]\n");
	}
	return 0;
}


static int
dot_op(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
       TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int which;			/* which analysis we are performing */
	int error;			/* error code temporary */

	NG_IGNORE(line);
	NG_IGNORE(tab);
	NG_IGNORE(gnode);

	/* .op */
	which = ft_find_analysis("OP");
	if (which == -1) {
		LITERR("DC operating point analysis unsupported\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Operating Point", &foo, task));
	return (0);
}


static int
dot_disto(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
          TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int which;			/* which analysis we are performing */
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	char *steptype;		/* ac analysis, type of stepping function */

	NG_IGNORE(gnode);

	/* .disto {DEC OCT LIN} NP FSTART FSTOP <F2OVERF1> */
	which = ft_find_analysis("DISTO");
	if (which == -1) {
		LITERR("Small signal distortion analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Distortion Analysis", &foo, task));
	INPgetTok(&line, &steptype, 1);	/* get DEC, OCT, or LIN */
	ptemp.iValue = 1;
	GCA(INPapName, (ckt, which, foo, steptype, &ptemp));
	parm = INPgetValue(ckt, &line, IF_INTEGER, tab);	/* number of points */
	GCA(INPapName, (ckt, which, foo, "numsteps", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* fstart */
	GCA(INPapName, (ckt, which, foo, "start", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* fstop */
	GCA(INPapName, (ckt, which, foo, "stop", parm));
	if (*line) {
		parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* f1phase */
		GCA(INPapName, (ckt, which, foo, "f2overf1", parm));
	}
	return (0);
}


static int
dot_ac(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
       TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	int which;			/* which analysis we are performing */
	char *steptype;		/* ac analysis, type of stepping function */

	NG_IGNORE(gnode);

	/* .ac {DEC OCT LIN} NP FSTART FSTOP */
	which = ft_find_analysis("AC");
	if (which == -1) {
		LITERR("AC small signal analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "AC Analysis", &foo, task));
	INPgetTok(&line, &steptype, 1);	/* get DEC, OCT, or LIN */
	ptemp.iValue = 1;
	GCA(INPapName, (ckt, which, foo, steptype, &ptemp));
	tfree(steptype);
	parm = INPgetValue(ckt, &line, IF_INTEGER, tab); /* number of points */
	GCA(INPapName, (ckt, which, foo, "numsteps", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* fstart */
	GCA(INPapName, (ckt, which, foo, "start", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* fstop */
	GCA(INPapName, (ckt, which, foo, "stop", parm));
	return (0);
}

static int
dot_pz(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
       TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	int which;			/* which analysis we are performing */
	char *steptype;		/* ac analysis, type of stepping function */

	NG_IGNORE(gnode);

	/* .pz nodeI nodeG nodeJ nodeK {V I} {POL ZER PZ} */
	which = ft_find_analysis("PZ");
	if (which == -1) {
		LITERR("Pole-zero analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Pole-Zero Analysis", &foo, task));
	parm = INPgetValue(ckt, &line, IF_NODE, tab);
	GCA(INPapName, (ckt, which, foo, "nodei", parm));
	parm = INPgetValue(ckt, &line, IF_NODE, tab);
	GCA(INPapName, (ckt, which, foo, "nodeg", parm));
	parm = INPgetValue(ckt, &line, IF_NODE, tab);
	GCA(INPapName, (ckt, which, foo, "nodej", parm));
	parm = INPgetValue(ckt, &line, IF_NODE, tab);
	GCA(INPapName, (ckt, which, foo, "nodek", parm));
	INPgetTok(&line, &steptype, 1);	/* get V or I */
	ptemp.iValue = 1;
	GCA(INPapName, (ckt, which, foo, steptype, &ptemp));
	INPgetTok(&line, &steptype, 1);	/* get POL, ZER, or PZ */
	ptemp.iValue = 1;
	GCA(INPapName, (ckt, which, foo, steptype, &ptemp));
	return (0);
}


static int
dot_dc(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
       TSKtask *task, CKTnode *gnode, JOB *foo)
{
	char *name;			/* the resistor's name */
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	int which;			/* which analysis we are performing */

	NG_IGNORE(gnode);

	/* .dc SRC1NAME Vstart1 Vstop1 Vinc1 [SRC2NAME Vstart2 */
	/*        Vstop2 Vinc2 */
	which = ft_find_analysis("DC");
	if (which == -1) {
		LITERR("DC transfer curve analysis unsupported\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "DC transfer characteristic", &foo, task));
	INPgetTok(&line, &name, 1);
	INPinsert(&name, tab);
	ptemp.uValue = name;
	GCA(INPapName, (ckt, which, foo, "name1", &ptemp));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* vstart1 */
	GCA(INPapName, (ckt, which, foo, "start1", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* vstop1 */
	GCA(INPapName, (ckt, which, foo, "stop1", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* vinc1 */
	GCA(INPapName, (ckt, which, foo, "step1", parm));
	if (*line) {
		INPgetTok(&line, &name, 1);
		INPinsert(&name, tab);
		ptemp.uValue = name;
		GCA(INPapName, (ckt, which, foo, "name2", &ptemp));
		parm = INPgetValue(ckt, &line, IF_REAL, tab); /* vstart2 */
		GCA(INPapName, (ckt, which, foo, "start2", parm));
		parm = INPgetValue(ckt, &line, IF_REAL, tab); /* vstop2 */
		GCA(INPapName, (ckt, which, foo, "stop2", parm));
		parm = INPgetValue(ckt, &line, IF_REAL, tab); /* vinc2 */
		GCA(INPapName, (ckt, which, foo, "step2", parm));
	}
	return 0;
}


static int
dot_tf(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
       TSKtask *task, CKTnode *gnode, JOB *foo)
{
	char *name;			/* the resistor's name */
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	int which;			/* which analysis we are performing */
	char *nname1;		/* the first node's name */
	char *nname2;		/* the second node's name */
	CKTnode *node1;		/* the first node's node pointer */
	CKTnode *node2;		/* the second node's node pointer */

	/* .tf v( node1, node2 ) src */
	/* .tf vsrc2             src */
	which = ft_find_analysis("TF");
	if (which == -1) {
		LITERR("Transfer Function analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Transfer Function", &foo, task));
	INPgetTok(&line, &name, 0);
	/* name is now either V or I or a serious error */
	if (*name == 'v' && strlen(name) == 1) {
		if (*line != '(' ) {
			/* error, bad input format */
		}
		INPgetNetTok(&line, &nname1, 0);
		INPtermInsert(ckt, &nname1, tab, &node1);
		ptemp.nValue = node1;
		GCA(INPapName, (ckt, which, foo, "outpos", &ptemp));
		if (*line != ')') {
			INPgetNetTok(&line, &nname2, 1);
			INPtermInsert(ckt, &nname2, tab, &node2);
			ptemp.nValue = node2;
			GCA(INPapName, (ckt, which, foo, "outneg", &ptemp));
			ptemp.sValue = tprintf("V(%s,%s)", nname1, nname2);
			GCA(INPapName, (ckt, which, foo, "outname", &ptemp));
		} else {
			ptemp.nValue = gnode;
			GCA(INPapName, (ckt, which, foo, "outneg", &ptemp));
			ptemp.sValue = tprintf("V(%s)", nname1);
			GCA(INPapName, (ckt, which, foo, "outname", &ptemp));
		}
	} else if (*name == 'i' && strlen(name) == 1) {
		INPgetTok(&line, &name, 1);
		INPinsert(&name, tab);
		ptemp.uValue = name;
		GCA(INPapName, (ckt, which, foo, "outsrc", &ptemp));
	} else {
		LITERR("Syntax error: voltage or current expected.\n");
		return 0;
	}
	INPgetTok(&line, &name, 1);
	INPinsert(&name, tab);
	ptemp.uValue = name;
	GCA(INPapName, (ckt, which, foo, "insrc", &ptemp));
	return (0);
}


static int
dot_tran(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
         TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	int which;			/* which analysis we are performing */
	double dtemp;		/* random double precision temporary */
	char *word;			/* something to stick a word of input into */

	NG_IGNORE(gnode);

	/* .tran Tstep Tstop <Tstart <Tmax> > <UIC> */
	which = ft_find_analysis("TRAN");
	if (which == -1) {
		LITERR("Transient analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Transient Analysis", &foo, task));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* Tstep */
	GCA(INPapName, (ckt, which, foo, "tstep", parm));
	parm = INPgetValue(ckt, &line, IF_REAL, tab);	/* Tstop */
	GCA(INPapName, (ckt, which, foo, "tstop", parm));
	if (*line) {
		dtemp = INPevaluate(&line, &error, 1);	/* tstart? */
		if (error == 0) {
			ptemp.rValue = dtemp;
			GCA(INPapName, (ckt, which, foo, "tstart", &ptemp));
			dtemp = INPevaluate(&line, &error, 1);	/* tmax? */
			if (error == 0) {
				ptemp.rValue = dtemp;
				GCA(INPapName, (ckt, which, foo, "tmax", &ptemp));
			}
		}
	}
	if (*line) {
		INPgetTok(&line, &word, 1);	/* uic? */
		if (strcmp(word, "uic") == 0) {
			ptemp.iValue = 1;
			GCA(INPapName, (ckt, which, foo, "uic", &ptemp));
		} else {
			LITERR(" Error: unknown parameter on .tran - ignored\n");
		}
	}
	return (0);
}


static int
dot_sens(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
         TSKtask *task, CKTnode *gnode, JOB *foo)
{
	char *name;			/* the resistor's name */
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	int which;			/* which analysis we are performing */
	char *nname1;		/* the first node's name */
	char *nname2;		/* the second node's name */
	CKTnode *node1;		/* the first node's node pointer */
	CKTnode *node2;		/* the second node's node pointer */
	char *steptype;		/* ac analysis, type of stepping function */

	which = ft_find_analysis("SENS");
	if (which == -1) {
		LITERR("Sensitivity unsupported.\n");
		return (0);
	}

	IFC(newAnalysis, (ckt, which, "Sensitivity Analysis", &foo, task));

	/* Format is:
	 *      .sens <output>
	 *      + [ac [dec|lin|oct] <pts> <low freq> <high freq> | dc ]
	 */
	/* Get the output voltage or current */
	INPgetTok(&line, &name, 0);
	/* name is now either V or I or a serious error */
	if (*name == 'v' && strlen(name) == 1) {
		if (*line != '(') {
			LITERR("Syntax error: '(' expected after 'v'\n");
			return 0;
		}
		INPgetNetTok(&line, &nname1, 0);
		INPtermInsert(ckt, &nname1, tab, &node1);
		ptemp.nValue = node1;
		GCA(INPapName, (ckt, which, foo, "outpos", &ptemp));

		if (*line != ')') {
			INPgetNetTok(&line, &nname2, 1);
			INPtermInsert(ckt, &nname2, tab, &node2);
			ptemp.nValue = node2;
			GCA(INPapName, (ckt, which, foo, "outneg", &ptemp));
			ptemp.sValue = tprintf("V(%s,%s)", nname1, nname2);
			GCA(INPapName, (ckt, which, foo, "outname", &ptemp));
		} else {
			ptemp.nValue = gnode;
			GCA(INPapName, (ckt, which, foo, "outneg", &ptemp));
			ptemp.sValue = tprintf("V(%s)", nname1);
			GCA(INPapName, (ckt, which, foo, "outname", &ptemp));
		}
	} else if (*name == 'i' && strlen(name) == 1) {
		INPgetTok(&line, &name, 1);
		INPinsert(&name, tab);
		ptemp.uValue = name;
		GCA(INPapName, (ckt, which, foo, "outsrc", &ptemp));
	} else {
		LITERR("Syntax error: voltage or current expected.\n");
		return 0;
	}

	INPgetTok(&line, &name, 1);
	if (name && !strcmp(name, "pct")) {
		ptemp.iValue = 1;
		GCA(INPapName, (ckt, which, foo, "pct", &ptemp));
		INPgetTok(&line, &name, 1);
	}
	if (name && !strcmp(name, "ac")) {
		INPgetTok(&line, &steptype, 1);	/* get DEC, OCT, or LIN */
		ptemp.iValue = 1;
		GCA(INPapName, (ckt, which, foo, steptype, &ptemp));
		parm = INPgetValue(ckt, &line, IF_INTEGER, tab); /* number of points */
		GCA(INPapName, (ckt, which, foo, "numsteps", parm));
		parm = INPgetValue(ckt, &line, IF_REAL, tab); /* fstart */
		GCA(INPapName, (ckt, which, foo, "start", parm));
		parm = INPgetValue(ckt, &line, IF_REAL, tab); /* fstop */
		GCA(INPapName, (ckt, which, foo, "stop", parm));
		return (0);
	} else if (name && *name && strcmp(name, "dc")) {
		/* Bad flag */
		LITERR("Syntax error: 'ac' or 'dc' expected.\n");
		return 0;
	}
	return (0);
}


#ifdef WANT_SENSE2
static int
dot_sens2(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
          TSKtask *task, CKTnode *gnode, JOB *foo)
{
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	int which;			/* which analysis we are performing */
	char *token;		/* a token from the line */

	NG_IGNORE(gnode);

	/* .sens {AC} {DC} {TRAN} [dev=nnn parm=nnn]* */
	which = ft_find_analysis("SENS2");
	if (which == -1) {
		LITERR("Sensitivity-2 analysis unsupported\n");
		return (0);
	}

	IFC(newAnalysis, (ckt, which, "Sensitivity-2 Analysis", &foo, task));

	while (*line) {

            IFparm *if_parm;

            /* read the entire line */
            INPgetTok(&line, &token, 1);

            if_parm = ft_find_analysis_parm(which, token);

            if (!if_parm) {
                /* didn't find it! */
                LITERR(" Error: unknown parameter on .sens-ignored \n");
                continue;
            }

            /* found it, analysis which, parameter i */
            if (if_parm->dataType & IF_FLAG) {

                /* one of the keywords! */
                ptemp.iValue = 1;
                error = ft_sim->setAnalysisParm (ckt, foo,
                                                 if_parm->id,
                                                 &ptemp,
                                                 NULL);
                if (error)
                    current->error = INPerrCat(current->error, INPerror(error));

            } else {

                parm = INPgetValue(ckt, &line, if_parm->dataType, tab);
                error = ft_sim->setAnalysisParm (ckt, foo,
                                                 if_parm->id,
                                                 parm,
                                                 NULL);
                if (error)
                    current->error = INPerrCat(current->error, INPerror(error));
            }
	}

	return (0);
}
#endif

#ifdef WITH_PSS
/*SP: Steady State Analyis */
static int
dot_pss(char *line, void *ckt, INPtables *tab, card *current,
        void *task, void *gnode, JOB *foo)
{
	int error;			/* error code temporary */
	IFvalue ptemp;		/* a value structure to package resistance into */
	IFvalue *parm;		/* a pointer to a value struct for function returns */
	char *nname;		/* the oscNode name */
	CKTnode *nnode;		/* the oscNode node */
	int which;			/* which analysis we are performing */
	char *word;			/* something to stick a word of input into */

	NG_IGNORE(gnode);

	/* .pss Fguess StabTime OscNode <UIC>*/
	which = ft_find_analysis("PSS");
	if (which == -1) {
		LITERR("Periodic steady state analysis unsupported.\n");
		return (0);
	}
	IFC(newAnalysis, (ckt, which, "Periodic Steady State Analysis", &foo, task));

	parm = INPgetValue(ckt, &line, IF_REAL, tab);		/* Fguess */
	GCA(INPapName, (ckt, which, foo, "fguess", parm));

	parm = INPgetValue(ckt, &line, IF_REAL, tab);		/* StabTime */
	GCA(INPapName, (ckt, which, foo, "stabtime", parm));

	INPgetNetTok(&line, &nname, 0);
	INPtermInsert(ckt, &nname, tab, &nnode);
	ptemp.nValue = nnode;
	GCA(INPapName, (ckt, which, foo, "oscnode", &ptemp));	/* OscNode given as string */

	parm = INPgetValue(ckt, &line, IF_INTEGER, tab);		/* PSS points */
	GCA(INPapName, (ckt, which, foo, "points", parm));

	parm = INPgetValue(ckt, &line, IF_INTEGER, tab);		/* PSS harmonics */
	GCA(INPapName, (ckt, which, foo, "harmonics", parm));

	parm = INPgetValue(ckt, &line, IF_INTEGER, tab);		/* SC iterations */
	GCA(INPapName, (ckt, which, foo, "sc_iter", parm));

	parm = INPgetValue(ckt, &line, IF_REAL, tab);		/* Steady coefficient */
	GCA(INPapName, (ckt, which, foo, "steady_coeff", parm));

	if (*line) {
		INPgetTok(&line, &word, 1);	/* uic? */
		if (strcmp(word, "uic") == 0) {
			ptemp.iValue = 1;
			GCA(INPapName, (ckt, which, foo, "uic", &ptemp));
		} else {
			fprintf(stderr,"Error: unknown parameter %s on .pss - ignored\n", word);
		}
	}
	return (0);
}
/* SP */
#endif

static int
dot_options(char *line, CKTcircuit *ckt, INPtables *tab, card *current,
            TSKtask *task, CKTnode *gnode, JOB *foo)
{
	NG_IGNORE(line);
	NG_IGNORE(gnode);
	NG_IGNORE(foo);

	/* .option - specify program options - rather complicated */
	/* use a subroutine to handle all of them to keep this    */
	/* subroutine managable.                                  */

	INPdoOpts(ckt, &(task->taskOptions), current, tab);
	return (0);
}


int
INP2dot(CKTcircuit *ckt, INPtables *tab, card *current, TSKtask *task, CKTnode *gnode)
{

	/* .<something> Many possibilities */
	char *token;		/* a token from the line, tmalloc'ed */
	JOB *foo = NULL;		/* pointer to analysis */
	/* the part of the current line left to parse */
	char *line = current->line;
	int rtn = 0;

	INPgetTok(&line, &token, 1);
	if (strcmp(token, ".model") == 0) {
		/* don't have to do anything, since models were all done in
		 * pass 1 */
		goto quit;
	} else if ((strcmp(token, ".width") == 0) ||
	           strcmp(token, ".print") == 0 || strcmp(token, ".plot") == 0) {
		/* obsolete - ignore */
		LITERR(" Warning: obsolete control card - ignored \n");
		goto quit;
	} else if ((strcmp(token, ".temp") == 0)) {
		/* .temp temp1 temp2 temp3 temp4 ..... */
		/* not yet implemented - warn & ignore */
		/*
		LITERR(" Warning: .TEMP card obsolete - use .options TEMP and TNOM\n");
		*/
		goto quit;
	} else if ((strcmp(token, ".op") == 0)) {
		rtn = dot_op(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".nodeset") == 0)) {
		goto quit;
	} else if ((strcmp(token, ".disto") == 0)) {
		rtn = dot_disto(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".noise") == 0)) {
		rtn = dot_noise(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".four") == 0)
	           || (strcmp(token, ".fourier") == 0)) {
		/* .four */
		/* not implemented - warn & ignore */
		LITERR("Use fourier command to obtain fourier analysis\n");
		goto quit;
	} else if ((strcmp(token, ".ic") == 0)) {
		goto quit;
	} else if ((strcmp(token, ".ac") == 0)) {
		rtn = dot_ac(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".pz") == 0)) {
		rtn = dot_pz(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".dc") == 0)) {
		rtn = dot_dc(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".tf") == 0)) {
		rtn = dot_tf(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	} else if ((strcmp(token, ".tran") == 0)) {
		rtn = dot_tran(line, ckt, tab, current, task, gnode, foo);
		goto quit;
#ifdef WITH_PSS
		/* SP: Steady State Analysis */
	} else if ((strcmp(token, ".pss") == 0)) {
		rtn = dot_pss(line, ckt, tab, current, task, gnode, foo);
		goto quit;
		/* SP */
#endif
	} else if ((strcmp(token, ".subckt") == 0) ||
	           (strcmp(token, ".ends") == 0)) {
		/* not yet implemented - warn & ignore */
		LITERR(" Warning: Subcircuits not yet implemented - ignored \n");
		goto quit;
	} else if ((strcmp(token, ".end") == 0)) {
		/* .end - end of input */
		/* not allowed to pay attention to additional input - return */
		rtn = 1;
		goto quit;
	} else if (strcmp(token, ".sens") == 0) {
		rtn = dot_sens(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	}
#ifdef WANT_SENSE2
	else if ((strcmp(token, ".sens2") == 0)) {
		rtn = dot_sens2(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	}
#endif
	else if ((strcmp(token, ".probe") == 0)) {
		/* Maybe generate a "probe" format file in the future. */
		goto quit;
	} else if ((strcmp(token, ".options") == 0)||
	           (strcmp(token,".option")==0) ||
	           (strcmp(token,".opt")==0)) {
		rtn = dot_options(line, ckt, tab, current, task, gnode, foo);
		goto quit;
	}
	/* Added by H.Tanaka to find .global option */
	else if (strcmp(token, ".global") == 0) {
		rtn = 0;
		LITERR(" Warning: .global not yet implemented - ignored \n");
		goto quit;
	}
	/* ignore .meas statements -- these will be handled after analysis */
	/* also ignore .param statements */
	/* ignore .prot, .unprot */
	else if (strcmp(token, ".meas") == 0 || strcmp(token, ".param") == 0 || strcmp(token, ".measure") == 0 ||
	         strcmp(token, ".prot") == 0 || strcmp(token, ".unprot") == 0) {
		rtn = 0;
		goto quit;
	}
	LITERR(" unimplemented control card - error \n");
quit:
	tfree(token);
	return rtn;
}
